Presentation is loading. Please wait.

Presentation is loading. Please wait.

Volume 6, Issue 8, Pages (August 1998)

Published byVeronika Setiabudi Modified over 5 years ago

Similar presentations

Presentation on theme: "Volume 6, Issue 8, Pages (August 1998)"— Presentation transcript:

1 Volume 6, Issue 8, Pages 971-982 (August 1998)
Structure of 3-isopropylmalate dehydrogenase in complex with 3-isopropylmalate at 2.0 å resolution: the role of Glu88 in the unique substrate-recognition mechanism  Katsumi Imada, Kenji Inagaki, Hideyuki Matsunami, Hiroshi Kawaguchi, Hidehiko Tanaka, Nobuo Tanaka, Keiichi Namba  Structure  Volume 6, Issue 8, Pages (August 1998) DOI: /S (98)

2 Figure 1 A scheme of the reactions catalyzed by decarboxylating dehydrogenases. The substrates of these enzymes have the common malate backbone. (a) 3-Isopropylmalate dehydrogenase (IPMDH), (b) isocitrate dehydrogenase (ICDH), and (c) tartrate dehydrogenase (TDH). Structure 1998 6, DOI: ( /S (98) )

3 Figure 2 Comparison of the structures of Thermus thermophilus (Tf) IPMDH and Escherichia coli (Ec) ICDH. (a) Folding diagrams of IPMDH and ICDH. Circles and arrows represent α helices and β strands, respectively. (b) Stereo view ribbon representation of a Tf-IPMDH subunit. The N and C termini are also indicated. (c) Stereo view of a Tf-IPMDH dimer complexed with IPM superimposed on an Ec-ICDH dimer. Subunits are shown in different colors (cyan and blue, Tf-IPMDH; green and dark green, Ec-ICDH). A bound substrate molecule, IPM, is indicated as a ball-and-stick model for each of the two subunits. A least-squares superposition was achieved by minimizing the sum of the squared distances between corresponding Cα atoms with a root mean squared (rms) displacement of 2.0 å. The figures were generated with MOLSCRIPT [36] and RASTER3D [37]. Structure 1998 6, DOI: ( /S (98) )

4 Figure 3 Sequence alignment of Tf-IPMDH, Tt-IPMDH and Ec-ICDH based on the crystal structures. The secondary structures of IPMDH and ICDH are shown: α helices, green boxes; β strands, red boxes. Elements of the secondary structures are indicated by α for an α helix and β for a strand of β sheet. Residues interacting with the malate backbone of the substrates are highlighted in blue and residues interacting with the γ group of the substrates are highlighted in yellow. The numbering of residues is shown above each of the sequences. The identical residues between Tf-IPMDH and Tt-IPMDH are shaded. Structure 1998 6, DOI: ( /S (98) )

5 Figure 4 Structural comparison of unliganded Tt-IPMDH (open form) and Tf-IPMDH complexed with IPM (closed form). (a) A stereo view of the Cα trace of a Tf-IPMDH dimer complexed with IPM superimposed on a Tt-IPMDH apo dimer shows the movement of domain 1. The orientation is as in Figure 2c. The two subunits are shown in different colors (cyan and blue, Tf-IPMDH; yellow and orange, Tt-IPMDH). The bound substrate molecules of IPM are indicated as ball-and-stick models. The superposition was based on the corresponding Cα atoms in domain 2 of the two structures. The figure was generated with MOLSCRIPT [36] and RASTER3D [37]. (b) A close-up view of the mainchain trace around hinge 1, viewed from the axis of rigid-body rotation of domain 1. Tf-IPMDH and Tt-IPMDH are colored blue and yellow, respectively. The residues of hinge 1, Leu100, Tyr101 and Ala102 of Tf-IPMDH, are marked in green and the corresponding residues, Leu99, Phe100 and Ala101, of Tt-IPMDH are in red. (c) A close-up view of the mainchain around hinge 2, viewed from the opposite side to that in (b). Gly257 and Ser258 of Tf-IPMDH are marked in green and the corresponding residues, Gly252 and Ser253, of Tt-IPMDH are in red. Figures (b) and (c) were generated with the program O [32]. (d) Ramachandran plots of hinge 1. The φ and ψ angles are plotted with colored circles from Gly97 (red) to Arg105 (violet) for Tf-IPMDH. Leu100, Tyr101 and Ala102 are colored in yellow, green and cyan, respectively. The corresponding residues of Tt-IPMDH (from Ser96 to Arg104) are also plotted with the same color order as Tf-IPMDH. The circles are connected according to the residue number with continuous lines for Tf-IPMDH and dashed lines for Tt-IPMDH. (e) Ramachandran plots of hinge 2. The φ and ψ angles are plotted from Leu255 (red) to Ser264 (violet) for Tf-IPMDH. Gly257 and Ser258 are colored in orange and yellow, respectively. The corresponding residues of Tt-IPMDH (from Leu250 to Ser259) are also plotted with the same color order as Tf-IPMDH. The connections are indicated as in (d). Structure 1998 6, DOI: ( /S (98) )

6 Figure 5 An alignment of the amino acid sequences between strand C and strand F of IPMDHs from Kluyveromyces lactis (Kl), Candida utilis (Cu), Candida maltosa (Cm), Saccharomyces cerevisiae (Sc), Bacillus subtilis (Bs), Bacillus coagulans (Bc), Bacillus caldotenax (Bt), Escherichia coli (Ec), Salmonella typhimurium (St), Thermus thermophilus (Tt), Thermus aquaticus (Ta), and Thiobacillus ferrooxidans (Tf), and ICDHs from Escherichia coli and Thermus thermophilus. The secondary structures are shown: α helices, green boxes; β strands, red boxes. Elements of the secondary structure are indicated by α for an α helix and β for a strand of β sheet. The sequence numbers of Tf-IPMDH and Ec-ICDH are indicated. Structure 1998 6, DOI: ( /S (98) )

7 Figure 6 Comparison of the γ moiety recognition site. (a) A space-filling stereo drawing of the active site of Tf-IPMDH, viewed from the right-hand side of Figure 7b. The substrate is shown in ball-and-stick representation. Atoms are color-coded: oxygen, red; nitrogen, blue; and carbon, gray. A green ball represents a sulfur atom of a methionine residue and a small magenta ball indicates the magnesium ion. The carbon atoms in the hydrophobic pocket are highlighted in orange. Residues forming the hydrophobic pocket are labeled with their residue numbers. Schematic representations of the active site of (b) Tf-IPMDH (closed conformation), (c) Ec-ICDH (closed conformation), (d) St-IPMDH (closed conformation), (e) Tt-IPMDH IPM complex (open conformation). The orientation is as in (a). (d) Was generated by the superposition of IPM and Mg of the Tf-IPMDH binary complex onto the structure of St-IPMDH solved without IPM and Mg. The protein backbone is shown in a ribbon representation. The substrate molecules and sidechains lying in the active sites are shown in ball-and-stick representation. The color coding of the atoms is as in (a). Residues interacting with the γ moiety of the substrates are labeled with their residue numbers. The figures were generated with MOLSCRIPT [36] and RASTER3D [37]. Structure 1998 6, DOI: ( /S (98) )

8 Figure 7 The active-site structure of Tf-IPMDH. (a) Stereo view of the 2Fo–Fc electron-density map of the active site of the Tf-IPMDH–IPM complex with its final model. IPM is shown at the center of the figure. The green circle indicates the magnesium ion that is necessary for the enzymatic activity. The map was generated from the refined coordinates at 2.0 å. IPM and Mg were omitted from the phase calculation for the map. The figure was generated with the program O [32]. (b) Stereo view of the active-site structure of Tf-IPMDH superimposed on that of Ec-ICDH. The superposition matrix was calculated with the atomic coordinates of the residues interacting with the malate moiety of the substrates. The calculation was performed using the coordinates of the ICDH–NADP+–isocitrate complex (PDB code 1IDE; [14]). The residues interacting with substrate are colored by atom type: oxygen, red; nitrogen, blue; and carbon, gray. The bonds in the two different subunits are colored as in Figure 2c (cyan and light blue, Tf-IPMDH; and green and dark green, Ec-ICDH). IPM and isocitrate with oxygens in red are shown at the center of the figure in yellow and white, respectively. Dark blue balls indicate the magnesium ions. Residue numbers of Tf-IPMDH are also indicated. The figure was generated with MOLSCRIPT [36] and RASTER3D [37]. Structure 1998 6, DOI: ( /S (98) )

9 Figure 8 Structure of the possible ternary complex of IPMDH–NAD+–IPM. The structure was generated by superposition of the Ec-ICDH ternary complex onto the Tf-IPMDH binary complex. The superposition matrix was calculated with the atomic coordinates of the residues interacting with the malate moiety of the substrates. The rms displacement of the atoms of the two structures is 0.88 å. The protein backbone is indicated by a ribbon representation. The substrate molecules, the nicotinamide mononucleotide (NMN) moiety of the coenzyme NAD+, and sidechains in the active sites are shown as ball-and-stick models. Protein and substrate atoms are colored as in Figure 7b, the bonds of the coenzyme are in orange, and phosphate atoms are in light purple. The figure was generated with MOLSCRIPT [36] and RASTER3D [37]. Structure 1998 6, DOI: ( /S (98) )

Download ppt "Volume 6, Issue 8, Pages (August 1998)"

Similar presentations

Volume 10, Issue 8, Pages (August 2002)

Volume 10, Issue 8, Pages (August 2002)
Structure of the Rho Family GTP-Binding Protein Cdc42 in Complex with the Multifunctional Regulator RhoGDI  Gregory R. Hoffman, Nicolas Nassar, Richard.

Structure of the Rho Family GTP-Binding Protein Cdc42 in Complex with the Multifunctional Regulator RhoGDI  Gregory R. Hoffman, Nicolas Nassar, Richard.
Luke D Sherlin, John J Perona  Structure 

Luke D Sherlin, John J Perona  Structure 
R.Ian Menz, John E. Walker, Andrew G.W. Leslie  Cell 

R.Ian Menz, John E. Walker, Andrew G.W. Leslie  Cell 
Crystal Structure of the Tandem Phosphatase Domains of RPTP LAR

Crystal Structure of the Tandem Phosphatase Domains of RPTP LAR
Crystal structure of the chemotaxis receptor methyltransferase CheR suggests a conserved structural motif for binding S-adenosylmethionine  Snezana Djordjevic,

Crystal structure of the chemotaxis receptor methyltransferase CheR suggests a conserved structural motif for binding S-adenosylmethionine  Snezana Djordjevic,
Volume 10, Issue 8, Pages (August 2002)

Volume 10, Issue 8, Pages (August 2002)
Kristopher Josephson, Naomi J. Logsdon, Mark R. Walter  Immunity 

Kristopher Josephson, Naomi J. Logsdon, Mark R. Walter  Immunity 
Structure of an LDLR-RAP Complex Reveals a General Mode for Ligand Recognition by Lipoprotein Receptors  Carl Fisher, Natalia Beglova, Stephen C. Blacklow 

Structure of an LDLR-RAP Complex Reveals a General Mode for Ligand Recognition by Lipoprotein Receptors  Carl Fisher, Natalia Beglova, Stephen C. Blacklow 
Volume 8, Issue 2, Pages (February 2000)

Volume 8, Issue 2, Pages (February 2000)
Volume 10, Issue 10, Pages (October 2002)

Volume 10, Issue 10, Pages (October 2002)
The crystal structure of bovine bile salt activated lipase: insights into the bile salt activation mechanism  Xiaoqiang Wang, Chi-sun Wang, Jordan Tang,

The crystal structure of bovine bile salt activated lipase: insights into the bile salt activation mechanism  Xiaoqiang Wang, Chi-sun Wang, Jordan Tang,
Volume 9, Issue 5, Pages (May 2001)

Volume 9, Issue 5, Pages (May 2001)
Volume 5, Issue 1, Pages (January 1997)

Volume 5, Issue 1, Pages (January 1997)
Volume 124, Issue 2, Pages (January 2006)

Volume 124, Issue 2, Pages (January 2006)
Crystal structure of human mitochondrial NAD(P)+-dependent malic enzyme: a new class of oxidative decarboxylases  Yingwu Xu, Girija Bhargava, Hao Wu,

Crystal structure of human mitochondrial NAD(P)+-dependent malic enzyme: a new class of oxidative decarboxylases  Yingwu Xu, Girija Bhargava, Hao Wu,
Volume 8, Issue 5, Pages (May 2000)

Volume 8, Issue 5, Pages (May 2000)
Volume 10, Issue 12, Pages (December 2002)

Volume 10, Issue 12, Pages (December 2002)
Volume 3, Issue 11, Pages (November 1995)

Volume 3, Issue 11, Pages (November 1995)
Glycerol Dehydrogenase

Glycerol Dehydrogenase

Similar presentations

Ads by Google